The mass that is lost during nuclear fusion is converted into energy according to Einstein's equation, E=mc^2. This released energy is what powers the sun and other stars.
The mass is not lost but transformed in energy.
Mass can not be lost. According to the Law of Conservation of Mass, matter can not be created or destroyed.
Mass cannot be truly lost, as stated in the law of conservation of mass. It can change forms, such as being converted into energy through processes like nuclear reactions or chemical reactions. In these cases, the mass is not truly lost but rather transformed into a different state.
Mass.The total mass of the fragment nuclei after fission, or the composite nucleus after fusion,is less than the mass of the nuclei that entered the process.
Energy isn't "destroyed" and mass isn't "created" Basically mass is a "form" of energy. Much like ice is a "form" of water. So while one could, kinda, say "ice is destroyed when it melts into water" it isn't exactly true (even though it is no longer ice).
Some mass is "lost" during nuclear fusion and E = mc2 gives the amount of energy that this "lost" mass will be equal to.
In that case, the temperature is hot enough to create all known natural elements.
The mass is not lost but transformed in energy.
Mass can not be lost. According to the Law of Conservation of Mass, matter can not be created or destroyed.
False. Both mass and energy are conserved.
In nuclear fusion of hydrogen, the transformation of mass into energy occurs. This is in accordance with Einstein's equation E=mc^2, where a small amount of mass is converted into a large amount of energy.
Mass cannot be truly lost, as stated in the law of conservation of mass. It can change forms, such as being converted into energy through processes like nuclear reactions or chemical reactions. In these cases, the mass is not truly lost but rather transformed into a different state.
Mass.The total mass of the fragment nuclei after fission, or the composite nucleus after fusion,is less than the mass of the nuclei that entered the process.
Mass that is "lost" durning nuclear fusion is converted into binding energy to hold the newly formed atomic nucleus together. The lost mass, which is termed mass deficit, means the nucleus of the newly formed atom has less mass than the sum of the masses of the protons and neutrons that make up that nucleus. The stong reaction (strong nuclear force) participitates in the fursion reaction by mediating the conversion of mass into nuclear binding energy (or nuclear glue).It converts into the energy that is the desired end product of the reaction.
The lost mass typically represents the energy that has been converted into other forms, often according to Einstein's mass-energy equivalence principle (E=mc²). In nuclear reactions, for example, a small amount of mass is lost when nuclear binding energy is released, which manifests as energy. In broader contexts, lost mass can also refer to the mass that is no longer accounted for in a system due to processes like evaporation or conversion to other states of matter. Overall, it signifies a transformation rather than a disappearance, illustrating the interconnectedness of mass and energy.
The mass lost in nuclear fusion is converted into energy according to Einstein's famous equation, E=mc^2. This energy is released in the form of photons, such as gamma rays, and contributes to sustaining the fusion reaction.
Yes and no. Yes because most of the mass isn't a firecracker anymore, and no because mass is never lost or gained in a chemical reaction, which is what a firecracker explosion is. If you have a nuclear powered firecracker, however, it would be a definite yes because some mass would be converted into energy.